DE202013101776U1 - Storage system for storing static electricity present in the atmosphere - Google Patents

Abstract

A system for collecting and storing static electrical energy in the atmosphere, comprising: a control station (102); an airborne energy harvester (101) having a hull (1018), the control station (102) wirelessly communicating with the airborne energy harvester (101) to control movement of the airborne power harvester (101); a collection unit (1011) mounted on a surface of the hull (1018) for collecting the static electric energy in the atmosphere; and a memory module (1012) disposed inside the fuselage (1018), the memory module (1012) having at least one magnetic capacitance, the at least one magnetic capacitance (200) each comprising: a first magnetic portion (210); a second magnetic portion (220); and a dielectric portion (230) disposed between the first magnetic portion (210) and the second magnetic portion (220), wherein the dielectric portion (230) is configured to store the static electrical energy and have a thickness of at least 10 angstroms and 1 nm, respectively; wherein the static electrical energy collected in the collecting unit is transferred and stored in the at least one magnetic capacitance.

Description

Technical area

Embodiments of the present invention relate to an apparatus and method for collecting and / or storing static electrical energy. A specific embodiment relates to a storage system for the storage of static electrical energy in the atmosphere, or for storing static electricity present in the atmosphere.

Background of the invention

For many years, efforts have been made to find an effective and cost-effective source of energy for a variety of everyday energy-consuming, commercial, and technological energy-consuming facilities. One of the major concerns in using the energy source is how to conserve environmentally friendly, economically friendly resources.

It is known that with respect to the earth there are large amounts of electrical energy in the atmosphere and in lightning or thunderstorms. A lightning discharge contains energy of the order of 10 ¹⁰ joules. Various ideas and concepts have been proposed regarding the collection of lightning as an energy source.

It has been estimated that the total electrical energy of lightning across the earth is on the order of 10 ¹² watts. When a local build-up of electrical charge on earth exceeds the local breakdown potential of the atmosphere, a lightning discharge occurs. However, a lightning or lightning discharge is only a small fraction of the total electrical activity of the atmosphere. There is a continuous, invisible flow of charge from the ionosphere to the earth day and night over the entire surface of the globe, exceeding the global flash output many times. It would therefore be advantageous to collect and / or store this flow to provide usable electrical energy.

BRIEF SUMMARY Embodiments of the present invention relate to a system and method for collecting and storing static electrical energy in the atmosphere. In a particular embodiment, the system for collecting and / or storing static electrical energy in the atmosphere includes a control station, an airborne power harvester, a collection unit, and a memory module. The airborne energy harvester, i. the power generation plant in the air or existing on board a missile has a hull. The control station communicates with the airborne power plant to control the movement of the airborne power plant. The collection unit is mounted on a surface of the fuselage to collect the static electrical energy in the atmosphere or to collect the static electrical energy in the atmosphere. The memory module is located inside the fuselage. The memory module has at least one magnetic capacitor or a magnetic capacitor. The magnetic capacitance further includes a first magnetic portion, a second magnetic portion, and a dielectric portion formed between the first magnetic portion and the second magnetic portion. The dielectric portion is structured to store the electrical energy and has a thickness of at least 10 angstroms and one nm, respectively, to thereby reduce electrical energy leakage and preferably prevent electrical energy loss. The static electrical energy collected by the collection unit is transferred and stored in the at least one magnetic capacitance.

In one embodiment, the thickness of the dielectric portion is at least 10 angstroms or 1 nm, at least 100 angstroms or 10 nm, and / or 100 angstroms or 10 nm.

In one embodiment, the fuselage or transporter has sharp edges on each side of the fuselage.

In one embodiment, an operating altitude of the airborne power plant is 100 meters to 8000 meters.

In one embodiment, a power cable is attached to the collection unit to transfer the static electrical energy to the at least one magnetic capacitance.

In one embodiment, a switch is disposed between the power cable and the at least one magnetic capacitance.

In one embodiment, a controller is disposed inside the fuselage to control movement of the airborne power plant. The Control means further comprises a communication system for communicating with the control station in a wireless manner. The control device further comprises a detector for detecting or detecting a state of charge of the at least one magnetic capacitor. When the state of charge of the at least one magnetic capacitance is fully charged, the control station controls the controller to output a control signal to the switch to disconnect or disconnect a connection between the one or more power cables and the at least one magnetic capacitance.

In one embodiment, a lift element is disposed inside the fuselage, the lift element containing one or more gas pockets filled with a gas lighter than air to provide a lift force or to generate buoyancy force, which causes the airborne power generation plant to be airborne in the atmosphere or to float.

In one embodiment, the collection unit further comprises a plurality of bars attached to the top surface of the fuselage projecting outwardly toward the atmosphere.

In one embodiment, the memory module has a plurality of magnetic capacitors or capacitors connected in parallel and fabricated in a substrate. The substrate further comprises a first connector and a second connector such that the static electrical energy charges the magnetic capacitors through the first connector, and the magnetic capacitors charge the static electrical energy to an external device Feed the device through the second connector.

Brief description of the drawings

In the following, the appended drawings are described to further clarify the foregoing as well as other aspects, features, advantages, and embodiments of the present disclosure:

1 shows a schematic block diagram of a system for collecting and storing static electrical energy in the atmosphere or static electricity in the atmosphere;

2 FIG. 12 is a schematic diagram of an airborne or airborne power plant in accordance with one embodiment of the disclosure; FIG.

3 FIG. 12 is a schematic diagram of a magnetic capacitor for storing static electrical energy in the atmosphere of static electrical energy in accordance with an embodiment of the disclosure; FIG. and

4 FIG. 12 is a schematic diagram of a plurality of magnetic capacitors, fabricated together in a substrate, for storing static electrical energy in the atmosphere, in accordance with one embodiment of the disclosure. FIG.

Detailed description

In the following, various exemplary embodiments of the disclosure will be described in detail, wherein one or more examples of the disclosure are illustrated in the drawings. Each example is provided to illustrate the disclosure and is not intended to limit the disclosure. By way of example, features illustrated or described as part of one embodiment may also be used in conjunction with other embodiments to thereby form an additional embodiment. It is intended that the present disclosure include such modifications and variations.

1 shows a schematic block diagram of a system for collecting and storing the static electrical energy in the atmosphere, and for collecting and storing the static electrical energy present in the atmosphere. The system 100 to collect and store the static electrical energy in the atmosphere includes one or more airborne or airborne energy harvesters (Energy Harvester, AEH = "Airborne Energy Harvester") 101 and a control station 102 , In one embodiment, the control station is located 102 in a vehicle such as a car, the control station 102 but can also be in a truck, a ship, a train, a tractor trailer or a tractor or trailer truck, or even in an aircraft. The airborne or flying energy collecting plant or energy harvesting plant 101 is a remote-controlled vehicle (RPV, Remotely Piloted Vehicle) that carries an ultralight or ultra-light energy storage module with magnetic capacities ("Magnetic capacitors") is constructed. The airborne or flying power plant 101 is through the control station 102 remote controlled. The control station 102 preferably includes controls for yawing, pitching, and / or rolling the airborne power harvester 101 , The airborne energy harvester 101 is or should float in zones of high lightning or high lightning discharges or flies in such zones, which act as a bridge between zones of positive electrical charge and zones of negative electrical charge.

2 FIG. 12 is a schematic diagram of a powered air handling plant in accordance with one embodiment of the disclosure. FIG. The airborne energy harvester 101 has one or more bars or one or more bars 1011 , a memory module 1012 , a control device or a controller 1013 , and a lift element or lifting element or buoyancy element 1014 on. In one embodiment, the airborne power plant may 101 an airship, which may be, for example, a non-rigid airship, a semi-rigid or semi-rigid airship, or a fixed or rigid or rigid airship. The airborne energy harvester 101 may have aerodynamic stabilizers on the tail. The airborne energy harvester 101 has a hull or housing ("fuselage") 116 on. The hull 116 has sharp edges 1017 and 1018 on the respective side of the fuselage 1016 up, or will initiate or initiate atmospheric electrical discharges and store that energy or energy in the memory module 1012 ,

The rods or rods are on the surface of the fuselage 1016 the airborne or flying power plant 101 mounted and project towards the atmosphere. The memory module 1012 , the control device 1013 and the lifting or lifting element or buoyancy element 1014 are inside the hull 1016 the flying power plant 101 positioned. The rods collect the static electrical energy in the atmosphere. The voltage or energy cables 1015 transport energy through the rods or rods 1011 has been collected, to the memory module 1012 , In one embodiment, the memory module comprises 1012 Also, a power conversion device or the power conversion device, the energy or current of the shape, as by the rods or rods 1011 is collected, converted into a form that is used to load the memory module 1012 is more suitable. As one example, it may convert the high voltage static electrical output into a low voltage static electrical output to the memory module 1012 save.

The control device 1013 provides a monitoring and control system that allows a human operator, the flying power plant 101 To monitor and control, for example, control fins or steering ribs or steering fins of the airborne power plant 101 to adjust the hovering altitude of the flying power plant 101 to adjust, or loading the memory module 1012 to end. In one embodiment, the operating or working height of the airborne or flying power plant is located 101 at 1000 meters to 8000 meters to maximize the amount of static electrical energy available for harvesting or harvesting. The control device 1013 can also be a communication system 10131 for communication with the control station 102 contain. The control device 1013 can still have a detector 10132 for the detection or detection of the state of charge of the memory module 1012 contain. Data can be transferred between the control station 102 and the controller 1013 in the flying power plant 101 be transmitted. The data can, for example, the state of charge of the memory module 1012 and the height of the air-based energy harvesting plant or energy harvesting plant 101 contain. In one embodiment, a switch 10151 between the memory module 1012 and the power cables 1015 arranged. When the state of charge of the memory module 1012 fully loaded controls the control station 102 the controller 1013 in addition, a control signal to the switch 10151 spend to connect between the power cables 1015 and the memory module 1012 to interrupt or separate. The memory module 1012 is not or no longer charged by the static electrical energy.

The lift element or buoyancy element 1014 is lighter than air and generates a lifting or buoyant force through which the airborne energy harvester 101 to be supported or hovered in the atmosphere. In one embodiment, the lift element or buoyancy element 1014 one or more gas pockets filled with a gas that is lighter than air, such as helium, hydrogen, hot air, or any gas that is lighter than air.

In one embodiment, the memory module is 1012 housed in a box or a box. The box has an environmentally sealed cover for safety and protection against weather elements. The memory module 1012 is one or more magnetic Capacitors or capacities ("magnetic capacitor") 200 composed. The one or more magnetic capacitors or capacitors are based on the GMC (Giant Magnetic Capacitance) theory (GMC). It has a capacitance value that is 10 ⁶ - to 10 ¹⁷ times greater than that of a standard capacitor or a standard capacitance with equivalent dimensions and dielectric materials. A magnetic capacitor or a magnetic capacitor is an energy storage device.

3 FIG. 12 is a schematic representation of a magnetic capacitance for storing the static electrical energy in the atmosphere or the static electrical energy present in the atmosphere in accordance with an embodiment of the disclosure. FIG. A magnetic capacity 200 has a first magnetic section 210 , a second magnetic section 220 and a dielectric portion 230 on that between the first magnetic section 210 and the second magnetic portion 220 is configured or formed. The dielectric section 230 is a thin film, and it is the dielectric portion 230 formed or assembled from a dielectric material such as BaTiO ₃ or TiO ₃ . The dielectric section 230 is arranged to store electrical energy, and it is the first magnetic section 210 and the second magnetic section 220 for generating the insulating effect required to reduce or preferably prevent a current flowing therethrough (ie, electrical energy leakage). The dielectric section 230 further has a thickness of at least 10 angstroms or 1 nm for reducing or preferably preventing electrical energy leakage. In one embodiment, the thickness of the dielectric portion is 230 at least 10 angstroms or 1 nm, at least 100 angstroms or 10 nm, and / or 100 angstroms or 10 nm in order to reduce or preferably prevent electrical energy leakage or electrical energy loss.

In another embodiment, a plurality of magnetic capacitances 200 in a substrate 240 be made together or formed to the memory module 1012 to form, like this in 4 is shown. These magnetic capacities 200 are connected in parallel with each other and have a connector 250 and a connector 253 connected. The connector 250 is in the substrate 240 for connection to the power cable 1015 educated. The static electrical energy in the atmosphere passing through the rod (s) 1011 is collected, becomes the memory module 1012 through the power cable 1015 transfer. The connector 253 is also in the substrate 240 formed for the supply or supply of electrical energy to an external device or an external device. Furthermore, the memory module contains 1012 also an energy conversion device or power conversion device 260 , the energy or voltage or current from the mold in which he or she through the bars or rods 1011 is collected, converted into a form responsible for the charge of the magnetic capacitances 200 is more suitable. As an example, it may have the high voltage static electrical output into a low voltage static electrical output for charging the magnetic capacitances 200 convert.

In operation, the control station 102 then, if the prediction indicates weather conditions suitable for the collection of the static electrical energy in the atmosphere, sent to a specific region, and the airborne energy harvester (s) will become or become 101 released or started. The rods or rods 1011 Collect the charges, which are then directly in the memory module 1012 get saved.

It will be apparent to those skilled in the art that various modifications and changes may be made to the structure of the present disclosure without departing from the scope of the disclosure. In view of this, it is intended that the present disclosure cover modifications and variations of this disclosure provided they come within the scope of the following claims.

Embodiments of the invention relate to a system and method for collecting and storing static electrical energy in the atmosphere. One embodiment of the system includes a control station, at least one airborne power plant having a fuselage, a collection unit, and a storage module. The control station communicates with the airborne power plant (s) in wireless form to control the movement of the airborne power plant (s). The collection unit is attached to a surface of the housing for collecting the static electric energy in the atmosphere. The memory module is arranged in the interior of the fuselage and has at least one magnetic capacitance. The static electric energy collected by the collecting unit is transmitted to and stored in the at least one magnetic capacitance.

Claims (15)

A system for collecting and storing static electrical energy in the atmosphere, comprising: a control station ( 102 ); an airborne power plant ( 101 ), a hull ( 1018 ), wherein the control station ( 102 ) with the airborne power plant ( 101 ) communicates wirelessly to control the movement of the airborne power plant ( 101 ) to control; a collection unit ( 1011 ) attached to a surface of the fuselage ( 1018 ) is mounted to collect the static electrical energy in the atmosphere; and a memory module ( 1012 ), inside the hull ( 1018 ), wherein the memory module ( 1012 ) has at least one magnetic capacitance, wherein the at least one magnetic capacitance ( 200 ) each comprises: a first magnetic section ( 210 ); a second magnetic section ( 220 ); and a dielectric portion ( 230 ) between the first magnetic section ( 210 ) and the second magnetic section ( 220 ), wherein the dielectric portion ( 230 ) is configured to store the static electrical energy and has a thickness of at least 10 angstroms and 1 nm, respectively; wherein the static electrical energy collected in the collecting unit is transferred and stored in the at least one magnetic capacitance. A system according to claim 1, wherein the thickness of the dielectric portion ( 230 ) is at least 100 angstroms or 10 nm. System according to claim 1 or 2, in which the hull ( 1016 ) sharp edges ( 1017 . 1018 ) on each side of the fuselage ( 1016 ) having. System according to one of the preceding claims, wherein an operating altitude of the airborne power plant ( 101 ) in a range of 1000 meters to 8000 meters. System according to one of the preceding claims, in which a power cable ( 1015 ) at the collecting unit ( 1011 ) for transmitting the static electric power to the at least one magnetic capacitance. System according to claim 5, wherein a switch ( 10151 ) between the power cable ( 1015 ) and the at least one magnetic capacitance ( 200 ) is arranged. System according to one of the preceding claims, further comprising a control device ( 1013 ) for the control of the movement of the airborne power plant ( 101 ), wherein the control device in the interior of the fuselage ( 1016 ) is arranged. System according to Claim 7, in which the control device ( 1013 ) a communication system for wireless communication with the control station ( 102 ) having. A system according to claim 7 or 8, wherein the control means further comprises a detector for detecting a state of charge of the at least one magnetic capacitor (10). 200 ). System according to Claim 9, in which the control station ( 102 ) the control device ( 1013 ) when the state of charge of the at least one magnetic capacitance ( 200 ) is fully charged, for outputting a control signal to the switch ( 10151 ) for the interruption of the connection between the power cables and the at least one magnetic capacitor ( 200 ) controls. System according to one of the preceding claims, further comprising a lift element ( 1014 ) located inside the hull ( 1016 ), wherein the lift element comprises one or more gas pockets filled with a gas that is lighter than air to generate a buoyant force that the airborne power plant ( 101 ) caused to be carried or fly in the atmosphere. System according to one of the preceding claims, wherein the collecting unit comprises a plurality of bars ( 1011 ) located on the surface of the fuselage ( 1016 ) are mounted and protrude outward in the direction of the atmosphere. System according to one of the preceding claims, in which the memory module ( 1012 ) a plurality of magnetic capacitances ( 200 ) connected in parallel with each other and formed in a substrate. The system of claim 13, wherein the substrate further comprises a first connector and a second connector, wherein the static electrical energy comprises the plurality of magnetic capacitances (12). 200 ) through the first connector and the plurality of magnetic capacitors ( 200 ) feeds the static electrical energy to an external device via the second connector. System according to one of the preceding claims, in which the thickness of the dielectric section ( 230 ) is equal to 100 angstroms or 10 nm.

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